Deep Learning-Based Detection of Honey Storage Areas in Apis mellifera Colonies for Predicting Physical Parameters of Honey via Linear Regression.

IF 2.7 2区农林科学 Q1 ENTOMOLOGY

Insects Pub Date : 2025-05-29 DOI:10.3390/insects16060575

Watit Khokthong, Panpakorn Kritangkoon, Chainarong Sinpoo, Phuwasit Takioawong, Patcharin Phokasem, Terd Disayathanoowat

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引用次数: 0

Abstract

Traditional methods for assessing honey storage in beehives predominantly rely on manual visual inspection, which often leads to inconsistencies and inefficiencies. This study presents an automated deep learning approach utilizing the YOLOv11 model to detect, classify, and quantify honey cells within Apis mellifera frames across monthly sampling periods. The model's performance varied depending on image resolution and dataset partitioning. Using the free version of YOLOv11 with high-resolution images (960 × 960 resolution) and a dataset split of 90:5:5 for training, validating, and testing, the model achieved a mean average precision at IoU threshold of 0.5 (mAP@0.5) of 83.4% for uncapped honey cells and 80.5% for capped honey cells. A strong correlation (r = 0.94) was observed between the 90:5:5 and 80:10:10 dataset splits, indicating that increasing the volume of training data enhances classification accuracy. In parallel, the study investigated the relationship between the physical properties of honey and image-based honey storage detection. Of the four tested properties, electrical conductivity (R² = 0.19) and color (R² = 0.21) showed weak predictive power for honey storage area estimation, with even weaker associations found for pH and moisture content. The honey storage areas via 90:5:5 and 80:10:10 datasets moderately correlated (r = 0.44-0.46) with increasing electrical conductivity and color. Especially, electrical conductivity exhibited statistically significant correlations with dataset performance across different dataset splits (p < 0.05), suggesting some potential influence of chemical composition on model accuracy. Our findings demonstrate the viability of image-based honey classification as a reliable technique for monitoring beehive productivity. Additionally, the research on image-based honey detection can be a non-invasive solution for improved honey production, beehive productivity, and optimized beekeeping practices.

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基于深度学习的蜜蜂蜂群蜂蜜储存区检测及其线性回归预测蜂蜜物理参数

评估蜂箱中蜂蜜储存的传统方法主要依赖于人工目视检查，这往往导致不一致和效率低下。本研究提出了一种自动化深度学习方法，利用YOLOv11模型在每月采样周期内检测、分类和量化蜜蜂框架内的蜂蜜细胞。模型的性能取决于图像分辨率和数据集划分。使用免费版的YOLOv11高分辨率图像（960 × 960分辨率）和90:5:5的数据集分割进行训练、验证和测试，该模型在IoU阈值0.5 （mAP@0.5）下的平均精度为83.4%（未封盖蜂蜜细胞）和80.5%（封盖蜂蜜细胞）。在90:5:5和80:10:10数据集分割之间观察到强相关性（r = 0.94），表明增加训练数据量可以提高分类精度。同时，研究了蜂蜜的物理性质与基于图像的蜂蜜存储检测之间的关系。在四种测试特性中，电导率（R2 = 0.19）和颜色（R2 = 0.21）对蜂蜜储存面积的预测能力较弱，pH和水分含量的相关性更弱。通过90:5:5和80:10:10数据集，蜂蜜储存面积与电导率和颜色的增加适度相关（r = 0.44-0.46）。特别是，电导率与数据集性能在不同数据集分割中表现出统计学上显著的相关性（p < 0.05），这表明化学成分对模型精度有一定的潜在影响。我们的研究结果证明了基于图像的蜂蜜分类作为监测蜂巢生产力的可靠技术的可行性。此外，基于图像的蜂蜜检测研究可以成为提高蜂蜜产量，蜂巢生产力和优化养蜂实践的非侵入性解决方案。

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来源期刊

Insects Agricultural and Biological Sciences-Insect Science

CiteScore

5.10

自引率

10.00%

发文量

1013

审稿时长

21.77 days

期刊介绍： Insects (ISSN 2075-4450) is an international, peer-reviewed open access journal of entomology published by MDPI online quarterly. It publishes reviews, research papers and communications related to the biology, physiology and the behavior of insects and arthropods. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. There is no restriction on the length of the papers. The full experimental details must be provided so that the results can be reproduced. Electronic files regarding the full details of the experimental procedure, if unable to be published in a normal way, can be deposited as supplementary material.